Hydraulic rapid traverse



y 6 o. KYLIN ETAL. 2,400,237

' HYDRAULIC RAPIDD TRAVERSE Filed Nov. 18, 1942 Y s Sheets-Sheet 1 OSKARKYUN HENRIK O. KYLIN TORS M ICHAE L L. VALENTINO THE/A ATTORNEYS May14,1946. 0. KYLIN ETAL HYDRAULIC RAPID TRAVERSE 5 Sheets-Sheet .2

Filed NOV. 18, 1942 IN V EN TORS Fla-3- osKAR KYMN HENREfi O.KYLH

' GHAEL L. VALENTaNo THE/R A TTORNEYS May 14, 1946.

KYLIN ETAL 2 ,400,23%

HYDRAULIC RAPID TRAVERSE (U b o m M 5; 0 q a 3, l

f l v :81 I y [52 I S a I g;

E Q Q a a I v d a vi w I? 40* I 5 g 8? l 3 k 8 y 31 N h g g 6 3 8 z 1 a)g l I ll 8 I'm 7 N N -1 11 rQ Q Q g I OSKAR KYLIN HENRIK 0. KYLININVENIORS f MICHAEL L. VALENTINO BY E fia 'yrnlrfl u Filed Nov. 18, 19425 Sheets-Sheet 3 THE/R ATTORNEYS May 14; 19 46.

0. KYLIN ETAL IIYIJEUW1L .IC RAPID TRAVERSE I Filed Nw 18, 1942 5Sheets-Sheet 4 OSKAR K LlN HENRIK O. KYLIN IN VEN TORS MICHAEL L.VALENTINO MWC Patented Mayl4, 1946 Oskar Kylin, Henrik 0.-Kylin, andMichael L.

Valentino, Cleveland Heights, Ohio, aasignors to Bardons and Oliver,Inc., Cleveland, Ohio, a

corporation of Ohio Application November 1a, 1942, Serial No. 465,966

X 2 Claims.

Our invention relates to machine tools and more particularly to meansfor selecting or preselecting and controlling the rate of feed oi aslide member.

It is one 01' the objects of our invention to provide in a machine toolmeans for controlling the rate of feed of a slide member carrying toolsor material to be worked by tools.

Another object of the invention is to provide in amachine toolhydraulically actuated means for selecting or preselecting the rate offeed of a.

slide member.

A further object of the invention is the provision of a feed mechanismfor a tool or work slide in which the mechanism may be caused to feedthe slide at selected rates of feed along a machine tool bed.

Another object of the invention resides in a feed slide member havingmeans associated therewith by which the slide may be caused to be fedalong a machine bed at any one of a plurality of selected rates of feed,said means including a selective speed transmission, hydraulicallyactuated means for a selected gear ratio in the transmission, and asingle control member for controlling the operation of the hydraulicmeans.

A further object of the invention resides in the provision of a singlecontrol member within convenient reach of a machine tool operator,controlling the operation of a feed tool or work supporting slidemember.

' Another purpose of the invention is to provide in a machine tool asingle compact means for selecting or preselecting the rates of feed ofa tool slide and controlling the operation means for eilecting selectedgear ratios for traversing the slide at difierent rates oi teed along amachine tool bed.

A still further object oi the invention consists in providing in amachine tool a compact unit comprising means for selecting orprcselecting the rates of feed of a tool slide, and a control member foractuating hydraulic means whereby to eflect a selected gear ratio forfeeding the tool slide at a selected rate 01' ieed along a machine toolbed.

Other objects and advantages of our invention will become more apparentas the following dev scription of an embodiment progresses, referencebeing made to the accompanying drawings in which like referencecharacters are employed to designate like parts throughout the same.

In the drawings: Figure 1 is airont elevation of a slidable tool or workcarrying member of a machine tool, 55 a tool or work carrying slidemember which is showing means for seiectingor preselecting the rate offeed of the all "e member and together with control means for, il'ectinga selected gear ratio in the sliding gear transmission housed within theapron ofthe/slide member in accordance with our invention;

Figure 2 is a side elevation 01' the parts shown in Figure 1;

Figures is a view of the power transmission mechanism housed within theapron oi the slide member, showing some 01 the parts in section andillustrating the drive from the power teed shaft through thetransmission to eflect a movement or the carriage along the bed of themachine tool;

Figure 4 is a view of the hydraulic control valve and the selecting orpreselecting member, both shown partly in section. This view alsoillustrates the distribution of fluid under pressure to the several gearcluster actuating members;

Figure 5 is a front end view of a hydraulic preselector valve; I

Figure 6 is a side view of the same, showing the several ports at thevalve;

35 Figure 7 is a section taken on line 1-1 of-Figure 6;

Figure 8 is a section taken on line 8-! of Figure 6;

Figure 9 is a section taken on line ure 6;

Figure 10 is a section taken on line ill-Ill of Figure 6;

8-9 of Fi Figure i1 is a: section taken on line ii-li 015* Figure 6.

Figure 6;

Figure 13 is a section taken on line llli 01' Figure 6;- Figure 14 is asection taken on line "-44 of Figure 6;

Figure 15 is a section taken on line li -i5 of v Figure 6;

Figure 16 is an end view of the hydraulic pre- 45 selector valve controlmember;

Figure 17 is a sectional view through the hy- I draulic preselectorvalve control showing the valve opened as a result of depressing thecontrol lever in either of two directions.- In the drawings we haveillustrated our invention as applied to a machine tool such as a turretlathe, although it is to be understood that the invention may equallywell be applied to other machine tools which have as an essential partFigure 12 is a section taken on line l2-i2 of operated to feed a tool ora work piece, one relative to the other. I

The form of our invention illustrated in the accompanying drawings is soconstructed and arranged that the selecting and preselecting means and,the control member for effecting a gear change are located preferably onthe apron of the slide member and within easy and convenient reach ofthe operator, the control member being operable .in either of twodirections for opening the control valve.

Due to the construction and arrangement illustrated, the entire assemblyis compact and is free of protruding parts with respect to the front ofthe machine tool which might interfere with the operator's emciency andthe entire mechanism is well protected against metal particles or otherforeign matter which might quickly destroy the usefulness of the parts,if they had access to the gear box or to the hydraulic control means.

The invention as illustrated in the drawings may be described moreparticularly as follows:

The carriage is slidably mounted on the machine tool bed toslide alongthe bedways or track members 2 in either direction. A cross slide 3 issupported on the carriage in the usual manner. The carriage apron gearbox 4 houses a sliding gear transmission such as is illustrated morefully in Figure 3 for imparting a feed to the carriage and slidelongitudinally of the machine bed and for imparting a cross feed to thecross slide 3. The power feed to the cross slide may be engaged anddisengaged by mean of a lever 5, while a manual cross feed may beimparted to the cross slide by means of a hand wheel 6. Similarly,

power feed may be imparted to the slide by means of a lever I which maybe actuated to engage or disengage-the slide from power feed while ahand wheel 8 is provided for manual feed of the slide longitudinally ofthe machine bed. The stops 9 and I9 are provided on the ear box belowthe respective levers 5 and 'l to limit downward motion of the levers intheir disengaged positions.

Referring now more particularly to Figure 3, the sliding geartransmission which is housed within the slide apron derives its powerfrom a feed shaft II which has suitable power connec tion to a source ofpower. A drive gear I2 is rotatable with the feed shaft and is slidablykeyed to the shaft by means of a key l3 operating in a key-way I4. Thegear I2 is in mesh with a gear l5 keyed to a shaft Hi, there being athree clustered gear keyed to rotate with the shaft l6 but slidable onthe shaft along the key-ways or splines l8.

The three clustered gear comprises the gears I9, 20, and 2|, which areadapted to mesh selectively with the gears 22, 23, and 24, respectively,keyed to rotate with the shaft 25. We have shown in Figure 3 the gear l9in mesh-with the gear 22, which represents one selected gear ratiobetween the shafts l5 and 25.

A three clustered gear 26 is rotatable with the shaft 21 and is slidablethereon as indicated in the drawings. This cluster comprises the gears28, 29, and 39, which are adapted to mesh selectively with the gears 24,3| and 32, rotatable with the shaft 25. In the position shown, gear 29is in mesh with gear 3|. However, the gear cluster 26 is slidable s asto engage gear 28' with 24, 29 with 3|, or 39 with 32, as may. bedesired. The gear cluster 26 is slidable along the shaft 21 through afork connection 33, carried by a lever 34 which is actuated by hydraulicmeans, hereinafter referred to.

A worm 35 is also keyed to the shaft 2? and rotates therewith and isalways in mesh with a worm gear 35 to rotate the latter on a shaft 9'5.

The worm gear is provided with an annular gear section 38, which is inmesh with a gear 39 operating on a shaft 49, there being also a pinion4| fixed to the gear 39 engageable with a rack bar 42 which is mountedon the machine bed. Thus it will be seen that for whichever gear ratiois selected, there is power driving connection through the transmissionin the manner described above to drive the pinion 4| along the rack 42,thus imparting longitudinal motion to the slide carriage at the ratioselected.

Referring now more particularly to Figure 4, we have illustrated a formof a selector or preselector for the gear ratios together with'a controlmember for effecting a selected or preselected gear combination. Whilewe have illustrated hydraulic means for actuating the gear clusters, anyother The selector and control unit is mounted on the slide apronhousing the transmission and is arranged to extend along the bed of themachine and preferably 'well within the confines ofthe outer surface ofthe slide apron in order to avoid protruding parts and also to locatethe unit within easy and convenient reach of the operator, This isillustrated more clearly in Figures 1 and 2. A feed selector andindicating drum 43 is provided with a drum feed indicating plate 44extending around its periphery on which there are suitable indicia forindicating the various rates of feed which can be obtained from thesliding gear transmission.

The inner surface of the drum is provided with detents 45, each inalignment with'one of a series of indicia on the indicator plate, therebeing a spring pressed ball 46 carried by the apron wall and projectedoutwardly by the spring 41 to engage the detents as the drum is rotatedin either direction, thus enabling the operator to determine by theseating of the ball in the detents, the proper position of a selectedindicia and the rotary valve 53 with respect to the indicating arrow 48as shown in Figure 1. The control member includes a two way operatinghandle 49 pivotally mounted at 50 in the end of the drum 43 and having apair of outwardly diverging cams 5| for engagement with the valvestem 52as shown in Figure 4. The valve stem extends axially through the drumand the valve cylinder or chamber 53, and is slidable longitudinallytherein when the lever 49 is actuated in either direction. It is to benoted that the outer end of the valve stem is rounded to engage both ofthe cams 5| when the valve is closed, and to engage either one of thecams 5| when the handle 49 is rocked to open the valve 54 as shown inFigure 17. The valve I54 seats in the end of the cylinder, as at 55, and

.ing throughthe conduit 59.

When the lever 49 is depressed in either direc- .portion of the gear 28.

tion and the valve 54 is unseated, fluid under pressure entering theport 59 will enter the cylinder or chamber 53 behind the valve head fordistribution "through a plurality of distributing ports provided in thecylinder wall and communicating with certain selected ports in the valvecasing.

It will be noted that the rotatable selector drum 43 is rigidlyconnected with the operating handle support GI and with the hub of therotary valve cylinder 53 by means of the elongated bolts 62 which passthrough openings in the drum. In this manner the entire selector drum,control lever and rotary valve 53 may be rotated together as a unittoselect the proper valve position corresponding with the selected rate oftraverse of the slide along the machine bed.

The rotary valve casing 51 is provided with a series of ports 63, 64,65, 61, 68, 69, I8 and II,

of which the ports 63, 65, 66, 68, 69 and II are connected by conduits12, I3, '14, I5, I6 and II to deliver fluid under pressure to the gearcluster operating units or to exhaust fluid therefrom of the selectedports 63. 65, 68, 68, 68 or II Longitudinal by-passing'grooves or slotsare also formed along the outer surface of the rotary valve cylinder- 53and serve to communicate selected ports connected by conduits to thegear cluster sliding units, with the radially arranged fluid exhaustports 64, 61 and 18 whereby fluid may be exhausted from the cylindersI9, 88, 98 and 9|,

depending, of course, upon the direction of mo-- tion of the respectivepistons in these cylinders.

Attention is directed to the disclosure of the fluid supply and exhaustports and channels formed in the rotary valve cylinder 53 as shown 1 inFigures 7 to inclusive. We have not shown depending upon the position ofthe rotary valve 53. In' the'rctary valve-position shown in Figure 4 andin the respective sectional views shown in Figures 7 to 15 inclusive,fluid under pressure will be transmitted through the conduit 12 to theleft hand side of the piston I8 operating in the cylinder I9 therebytending to force the piston to the right.

A vent 88 in the cylinder prevents the formation of air or fluid trapsin the cylinder. The free end of the piston"rod 8labuts the member 82which is recessed to receive the headed end 83 of a gear clustershifting lever 84 pivotally supported in the casing 4 at 85.' a

The upper end of the lever 84 carries a forked member 86 which slidablyreceives the outer In Figure 3 the means for shifting the gear clusterI9, 28 and 2| is not shown but Figure 4 clearly illustrates its functionand relationship to this particular cluster.

The member 82 is attached to and moves with the piston rod 81 operatingin the cylinder 88 and carrying at its other end the piston 89. ConduitsI3 and I4 connect the ports .65 and 66 with the cylinder 88 on oppositesides of the piston 89.

A similar means is provided for sliding the gear cluster 28, '29 aand 38on its shaft 21 and consists of the cylinders 98 and 9|, the pistons 92and 93, and the respective piston rods 94 and 95, the rod 94 merelyabutting the member 96,

while the rod 95 is attached to the said member. The gear clustershifting lever 91 is pivotally carried at 98 in the casing'4 its lowerheaded end 99 seating in the recessed member 96, while its upper end isprovided with a forked gear engaging member 33 for slidably engaging therotating gear 29' of this sliding-cluster as indicated in Figure 3.

A conduit I5 connectsthe rotary valve casing port 68 with the cylinder98 on the left side of the piston 92, there being a vent hole I88 inthis cylinder to prevent the formation of air or fluid traps. ConduitsI6 and I1 connect the all of these ports and channels in thelongitudinal sections of the valve shown in Figures 4 and 17 for thepurpose of avoiding confusion, but it is intended that the cylinder ofthe rotary valve 53 shall be formed with such ports and channels in themanner disclosed in Figures 7 to 15 inclusive.

With the rotary valve in the position shown in Figures 4 and 17, port 63and conduit I2 will communicate with the interior of the rotary valve"cylinder 53 through the radial'port I8I. Likewise radial ports I82 andI83 will communicate fluid under pressure from the chamber 53 to thecon- 'duits I4 and II respectively. At the same time ports 69 and II ofthe rotary valve casing with v under pressure from within the chamber toany conduits I3, I5 and I6 will be open to exhaust through therespective channels I84, I and I86 and the respective exhaust ports 64,6! and I8 in the valve casing. Fluid exhausted from any of these exhaustports will be delivered to the interior of the gear box 4.

When the rotary valve is in the position just described and the operatoropens the valve 54 by moved to the left as fluid under pressure entersthe cylinder 88 from the conduit I4, thus centering the member 82 andbringing the gear 28 into mesh with'gear 23, and centering piston 89 inthe cylinder 88 between the ports leading to the conduits I3 and I4.

During the same operation, the cylinder 98 is open to exhaust throughthe conduit I5 and exhaust port 61, while fluid under pressure isdelivered through conduit 11 to the cylinder 9I against the right handside of the piston 93, forcing thepiston to the left and along with itthe piston 92 and the member 96. In this manner the arm 91 is shifted ina clockwise direction to engage the gears 38 and 32 (see Fig.

The selected gear ratio thus obtained may be.

described as represented in a drive through the shaft II, gears I2, I5,28, 23, 38 and 32 of the transmission proper. 7

As will be seen from Figures 7 to 15 inclusive, we have illustratedeight other rotative positions of the rotary valve 53 corresponding toselective gear ratios, although it is to be understood that the presentinvention contemplates additional or even fewer selective gear ratiosand corresponding feed rates, as desired.

To more clearly illustrate the selection of another rateof feed, let itbe supposed that the operator rotates the drum 43 together with therotary valve 53 and the operating handles 49, one

Figure 1. Referring now more particularly to Figures 7 to 15 inclusive,the rotary valve cylinder 53 is shown in transverse section. When thevalve is thus rotated one position, ports 63 and 64 in Figures '1 and 8,respectively, will be closed. In Figure 9 the radial port I81 will, whenthe valve 54 is opened, communicate fluid under pressure from the valvechamber 53' through the conduit 13 to the left hand side of piston 89,while channel I98 in Figures 10 and 11 will permit the exhaust of fluidfrom cylinder 88 through conduit 14, channel I68 and port 61. Thus thepiston 89 will move to the full end of its stroke to the right in Figure4. Since port 63 is closed, the piston 18 will remain in its previousposition as shown, but movement of the piston 89 to the right will swingthe arm in a counterclockwise direction to bring the gear 69 into meshwith gear 22, as shown in Figure 3. In Figure 12, radial port |09 willbe in alignment with the port 68 to deliver position in a clockwisedirection as viewed in just describedand the valve 54 is opened, ports63 and 64 remained closed as in Figures '1 and 8,

the piston 18 remaining in the position shown in Figure 4, In Figure 9radial port 6 communicates fluid under pressure from the chamber 53through port 65 and conduit 13 to the left side of piston 89 to retainit in its immediately previous position, while its opposite side is opento exhaust through conduit 14, port 61 and channel In as may be seenfrom Figures 10 and 11. .Channel ||1 also registers with ports 68, 69and 18 in this position of the drum relieving the left ends of cylinders90 and 9|. Fluid under pressure is delivered through radial port H8,port 1| and conduit 11 to the right side of piston 93 to rock the arm 91to the position shown in Figure 4. Thus, with the arm 84 rocked to theleft to engage gears l9 and 22 and the arm, 91 positioned-to engagegears 39 and 32, the selected gear ratio is obtained.

It will be noted that as the piston 93 moves to the left together withthe member 96, the memfluid under pressure through the conduit '15, to

- and with it the member 96, thus centering the arm 91 in acounterclockwise direction to disengage gears 30 and 32 which wereengaged in the previously selected feed rate and to engage gears 29 and3| as shown.

In Figures 13 and 14, channel H6 communicates with the ports 69 and 10,thus opening conduit 16 to exhaust through port 10. In Figure 15, radialport I will be in alignment with port 1| admitting fluid through conduit11 to the right hand side of piston 93 when valve 54 is depressed.

Thus the arm 91 will be held in this centered position and the resultingdrive ratio through the transmission will be that represented by themeshed gears I9 and 22, 29 and 3|, as shown in Figure 3.

When the operator rotates the selector drum 43 to the second nextposition in a clockwise direction from that shown in the drawings, ports63 and 64 will again be closed, but such rotation of the drum and rotaryvalve will bring radial port I I2, Figure 9, into register with port 65and, by opening valve 54, fluid under pressure will be delivered throughthe conduit 13 to the left hand side of piston 89.

In Figures 10 and 11 the ports 66 and 61 will be in communication withthe channel I I3 to exhaustfluid from the right hand end of the cylinder88 through conduit 14, while in Figure 12, port 68 will be closed tocylinder99. In Figure 13 the radial port ||4 will be in alignment withport 69 to feed fluid under pressure from the chamber 53 through conduit16 to the left hand end of cylinder 9| when the valve 54 is depressed,while as shown in Figures 14 and 15, ports 10 and 1| will be opened toexhaust fluid from the other end of cylinder 9| through conduit 1| andchannel 5.

In this selected position of the rotary valve, only cylinders 88 and 9|will receive fluid under pressure in the manner just described, thusretaining piston in its extreme right hand position as it was left inthe last preceding selected position of drum 43, and moving piston 93 toits extreme right hand position in the cylinder 9|. The gear ratios thusselected will be represented by meshed gears l9 and 22 and by meshedgears 24 and 28.

Continuing the description of the several selected rates of feed, itwill be seen that when the drum is rotated 60 the next position fromthat her will abut the free end of the piston rod 94 to slide the piston92'from a right hand to a left hand position in the cylinder 96. Whenthe drum 43 is rotated to the next successive selected speed indicationand the slide valve is depressed, it will be seen from Figures 7, 8 and9 that the respective ports 63, 64 and 65 are in communication withthechannel H to relieve the left hand ends of cylinders 19 and 88 throughconduits 12 and 13, respectively.

, In Figure 10 the port 66 is registered with radial port |20 to deliverfluid under pressure to the conduit 14 to the right hand side ofcylinder 88.

In Figure 11 port 61 is closed, while in Figure 12 port 68 is incommunication with a radial port |2| for delivering fluid under pressurethrough the conduit 15 to the left handend of cylinder 90.

In Figures 13 and 14- a channel I22 will register with ports 69 and 18to relieve the left hand end of cylinder 9| through a conduit 16, whilein Figure 15 the radial port I23 will register with port 1| to deliverfluid under'pressure through the conduit 11 to the right hand end ofcylinder 9|.

Under these conditions, it will be seen that the piston 89 will be movedto the left for it's full stroke, moving with it the piston 18 androcking the arm 84 inc. clockwise direction to engage ears 2| and 24. v

Likewise, the piston 92 will be urged to the right, while piston 93 willbe urged to the left to center the arm 91, thereby engaging gears 29 and3| to complete the selected gear ratio.

To select the next successive gear ratio, as indicated on the drum, theoperator rotates the drum.

will communicate with the ports 63, 64 and 65 and relieve the left handends of cylinders 19 and 98 through the conduits 12 and 13,respectively.

In Figure 10, the radial port I25 communicates fluid under pressurethrough the port 66 and conduit 14 to the right hand end of cylinder 88.

In Figures 11 and 12, ports 61 and 68 are closed.

In Figure 13, the radial port I26 communicates fluid under pressurefromthe interior of the rotary valve through port 69 and conduit 61 tothe left hand end of cylinder 9|, while in Figures 14 and 15 channelI21, which is in communication with ports 18 and 1|, relieves the righthand end of cylinder 9| through a conduit 11.

Under the conditions just described gears 2| and 24 will remain in mesh,while the arm 91 will have been shifted in counterclockwise direction toengage gears 28 and 24. The next position of the radial valve may bedescribed as follows: In Figures 7, 8 and 9 the channel I28 is inregistry. with ports 63, 64 and 65 to relieve the left hand ends ofcylinders 19 and'88 through conduits l2 and I3, respectively.

In Figure radial port I29 communicates fluid under pressure from thevalve chamber through port 66 and conduit I4 to the right hand end ofcylinder 88.

In Figures 11, 12, 13 and 14 channell30 communicates with ports 61, 68,69 and Ill to relieve the left hand ends of the cylinders 90 and 9|through the conduits and 16, while in Figure 15 the radial port I3| willbe in register with port ll to deliver fluid under pressure throughconduit ll to the right hand end of cylinder 9|.

Under these conditions, .arm 84 will remain in its previous position toengage gears 2I and 24,

while the piston 93 will be moved to the left to- I32, Figure '7, willdeliver fluid under pressure from the valve chamber through port 63 andconduit I2 to the left hand end of cylinder 19.

- In Figures 8 and 9 a channel I33 communicates with the ports 64 and 65to, relieve the left hand end of cylinder 88 through a conduit 13.

In Figure 10, a radial port I34 will deliver fluid under pressurethrough the port 66 and the conduit 14 to the right hand end ofcylinder88.

In Figure 11', the port 61 will be closed, while in Figure 12 the port68 will be in register with a radial port I35 to deliver fluid underpressure through a conduit 15 to the left hand end of cylin Figure 15, aradial port I31 will be in-register with the port II to deliver fluidunder pressure through the conduit TI to the right hand end of cylinder9|.

Under these conditions, pistons 18 and 92 will be forced to the rightfor their extreme strokes, while the pistons 89 and 93 will be moved tothe left to a centering position in their respective cyl- I inders, thuscentering the arms 84 and 91, re-

vided in the embodiment illustrated, a radial port.

I38 in Figure communicates fluid under pressure through a port 63 andconduit 12 to the left hand end of cylinder I9.

In Figures 8 and 9, channel I38 is in register with the ports 64 and 65to relieve the left hand end of cylinder 88 through a conduit I3.

In Figure 10 a'radial port I48 will register with the port 66 to deliverfluid under pressure through conduit 14 to the right hand end ofcylinder 88, while in Figures Y11 and 12 the ports 61 and 68 will beclosed; In Figure 13 a radial port I will register with port 69 todeliver fluid under pressure to the left hand and of cylinder 9|, while.spectively, to engage gears 28 and 23 and to enter with'ports I0 and IIto relieve the right hand end-of cylinder 9| through conduit 11.

Under these conditions, it will be seen that the pistons 18 and 89remain in the positions described in connection with the previous speedselection, so that the gears 20 and 23remainin mesh. However, piston 93will be forced to the right, removingthe member 96 from contact with theend of the piston rod 94 and rocking the arm 91 in a counterclockwisedirection to engage the gears 24 and.28.

While we have illustrated in the accompanying drawings nine selectivegear ratios and have deecribed herein these ratios in sequence, it is tobe understood that the invention contemplates any desired number ofspeed selections or gear ratios, be that more orless than thosedisclosed. It will also be noted that the drum 43 may be rotated ineither direction to select any predetermined gear ratio, so that theoperator may, with a minimum of efiort, make his selection withaccuracy, and by simple pressure on' the handle of the drum open theslide valve when the selection is made to immediately and simultaneouslyshift one or both of the sliding gear clusters in accordance with theselection made.

From the above detailed description of the embodiment illustrated, itwill readily be seen that any one of 'a plurality of feeds may beselected for feeding the sliding member. or apron 4, or the cross slide3, along or on the machine bed. The worm 35 on shaft 2'! is driven inresponse to the selected gear ratio, the drive being completed throughthe worm wheel 36 and the gears 38, 39

and H, gear 4I operating'along the rack bar 42 to impar feeding motionto the slide and cross slide. The lever I engages and disengages theselected rate of power feed to the carriage or V apron 4, while thelever 5 is employed to engage or disengage a selected rate of power feedto the cross slide 3. We have not illustrated in the drawings theprecise power feed engaging and disengaging members actuated by therespective levers 5 and I, since they may be of conventional form, suchas disc or cone clutches, toothed elements such as gears, and a rack orsliding gears.

By our invention the operator is enabled to select a rate of feed forthe carriage and/or the cross slide which is most practicable anddesirable selected or preselected rates and an apron on said slide, of aselective change speed gearing carried by the apron, hydraulicallyresponsive mechanism within the apron for shifting said gearing toobtain the different rates of feed available in said gearing, a drivenfeed member carried by the bed and having a driving connection with saidselective gearing in the apron, and a rate selecting device carried bythe apron and operable to select or preselect the desired rate of feedfor the slide and then to actuate said hydraulic responsive mechanism toobtain the selected rate of feed for the slide, said rate selectingdevice comprising as a unit a valve having a rotary selector cylinder,Said cylinder having a valve seat formed in one end, a valve headnormally seated on the seat, and a single actuator for said valves.

2. In a. machine tool having a, bed and a slide and an apron movable onthe bed, means in the apron for moving the slide at any one of aplurality of selected rates or movement, said means including a, changespeed gearing, hydraulically actuated device for effecting a gear ratiochange, a source of fluid pressure, and a combined fluid control andselecting or preselecting valve connected with said source of fluidpressure and with said devices, said valve having a part movable toselect or pre-select a desired rate of movement for the slide andanother part movable within said first named part for controlling thesupply of fluid pressure to said first part to actuate said deviceswhereby to impart a. movement to the slide at the selected rate, and asingle control member for moving said parts independently of oneanother.

OSKAR KYLIN.

HENRIK O. KYLIN.

MICHAEL L. VALENTINO.

